#include "fs.h" // Return the virtual address of this disk block. void* diskaddr(uint32_t blockno) { if (blockno == 0 || (super && blockno >= super->s_nblocks)) panic("bad block number %08x in diskaddr", blockno); return (char*) (DISKMAP + blockno * BLKSIZE); } // Is this virtual address mapped? bool va_is_mapped(void *va) { return (uvpd[PDX(va)] & PTE_P) && (uvpt[PGNUM(va)] & PTE_P); } // Is this virtual address dirty? bool va_is_dirty(void *va) { return (uvpt[PGNUM(va)] & PTE_D) != 0; } // Fault any disk block that is read in to memory by // loading it from disk. static void bc_pgfault(struct UTrapframe *utf) { void *addr = (void *) utf->utf_fault_va; uint32_t blockno = ((uint32_t)addr - DISKMAP) / BLKSIZE; int r; // Check that the fault was within the block cache region if (addr < (void*)DISKMAP || addr >= (void*)(DISKMAP + DISKSIZE)) panic("page fault in FS: eip %08x, va %08x, err %04x", utf->utf_eip, addr, utf->utf_err); // Sanity check the block number. if (super && blockno >= super->s_nblocks) panic("reading non-existent block %08x\n", blockno); // Allocate a page in the disk map region, read the contents // of the block from the disk into that page. // Hint: first round addr to page boundary. fs/ide.c has code to read // the disk. // // LAB 5: you code here: // Clear the dirty bit for the disk block page since we just read the // block from disk if ((r = sys_page_map(0, addr, 0, addr, uvpt[PGNUM(addr)] & PTE_SYSCALL)) < 0) panic("in bc_pgfault, sys_page_map: %e", r); // Check that the block we read was allocated. (exercise for // the reader: why do we do this *after* reading the block // in?) if (bitmap && block_is_free(blockno)) panic("reading free block %08x\n", blockno); } // Flush the contents of the block containing VA out to disk if // necessary, then clear the PTE_D bit using sys_page_map. // If the block is not in the block cache or is not dirty, does // nothing. // Hint: Use va_is_mapped, va_is_dirty, and ide_write. // Hint: Use the PTE_SYSCALL constant when calling sys_page_map. // Hint: Don't forget to round addr down. void flush_block(void *addr) { uint32_t blockno = ((uint32_t)addr - DISKMAP) / BLKSIZE; if (addr < (void*)DISKMAP || addr >= (void*)(DISKMAP + DISKSIZE)) panic("flush_block of bad va %08x", addr); // LAB 5: Your code here. panic("flush_block not implemented"); } // Test that the block cache works, by smashing the superblock and // reading it back. static void check_bc(void) { struct Super backup; // back up super block memmove(&backup, diskaddr(1), sizeof backup); // smash it strcpy(diskaddr(1), "OOPS!\n"); flush_block(diskaddr(1)); assert(va_is_mapped(diskaddr(1))); assert(!va_is_dirty(diskaddr(1))); // clear it out sys_page_unmap(0, diskaddr(1)); assert(!va_is_mapped(diskaddr(1))); // read it back in assert(strcmp(diskaddr(1), "OOPS!\n") == 0); // fix it memmove(diskaddr(1), &backup, sizeof backup); flush_block(diskaddr(1)); // Now repeat the same experiment, but pass an unaligned address to // flush_block. // back up super block memmove(&backup, diskaddr(1), sizeof backup); // smash it strcpy(diskaddr(1), "OOPS!\n"); // Pass an unaligned address to flush_block. flush_block(diskaddr(1) + 20); assert(va_is_mapped(diskaddr(1))); // Skip the !va_is_dirty() check because it makes the bug somewhat // obscure and hence harder to debug. //assert(!va_is_dirty(diskaddr(1))); // clear it out sys_page_unmap(0, diskaddr(1)); assert(!va_is_mapped(diskaddr(1))); // read it back in assert(strcmp(diskaddr(1), "OOPS!\n") == 0); // fix it memmove(diskaddr(1), &backup, sizeof backup); flush_block(diskaddr(1)); cprintf("block cache is good\n"); } void bc_init(void) { struct Super super; set_pgfault_handler(bc_pgfault); check_bc(); // cache the super block by reading it once memmove(&super, diskaddr(1), sizeof super); }